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1.
《热带海洋学报》2017,(3)
文章为大亚湾潮汐动力学系列研究论文的第二部分,主要关注大亚湾双峰水位现象和涨潮流速双峰现象的产生机制。基于前人研究成果和数学解析方法,得出在大亚湾海域水位的双峰现象主要是由以M_2为代表的半日分潮与四分之一日分潮(如M_4分潮)和六分之一日分潮(如M-_6分潮)共同作用造成的。并对产生双峰水位和涨潮流速双峰的条件进行了数学解析,利用数值模拟结果发现,M_2/M_4分潮组合在大亚湾并不能产生双峰水位现象,而M_2/M_6分潮组合只能在大亚湾东北的范和港产生双峰水位现象。相对而言,M_2、M_4和M_6 3个分潮叠加的组合在双峰水位的产生范围和双峰间落差上都要大于上述2个分潮的组合。在大亚湾湾内区域,涨潮流速双峰可以由M_2/M_4分潮组合,M_2/M_6分潮组合和M_2/M_4/M_6分潮组合产生,M_2/M_4/M_6分潮产生的涨潮流速双峰强度要比另外两组分潮组合大。 相似文献
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利用实测资料分析重构了大亚湾和大鹏湾潮汐水位“双峰”现象,确定了浅水分潮的异常增长是潮位“双峰”现象的主要成因,其中四分之一日分潮和六分之一日分潮起着至关重要的作用。通过SCHISM模型构建大亚湾和大鹏湾附近海域高分辨率水动力模型,模拟结果表明近岸海域,在大亚湾以东,潮汐类型为不规则全日潮,以西为不规则半日潮,在两个海湾内均为不规则半日潮;研究海域的潮流均表现为不规则半日潮流。四分之一日分潮和六分之一日分潮在大亚湾和大鹏湾的不同变形过程是造成两个相邻海湾水文差异的直接原因。通过构建不同底摩擦强度、消除水底地形以及改变海湾水深的数值实验研究表明,分潮传播方向与水深变浅方向是否一致,是导致两个海湾潮波浅水变形不同的根本原因。 相似文献
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采用POM海洋模式模拟了渤海潮汐的主要特征。4个主要天文分潮的计算结果与实测吻合较好,在此基础上进一步探讨了渤海3个主要浅水分潮的基本特征。根据模式计算结果发现:渤海M_4和MS_4潮波传播特征类似,均存在5个潮波系统,其中4个为逆时针旋转,1个为顺时针旋转,与前人的研究成果比较一致。此外,根据浅水分潮和产生浅水分潮的源分潮的关系式推算得到MS_4分潮的振幅和迟角,与直接通过调和分析得到MS_4分潮的振幅和迟角进行对比,结果也是比较符合。针对M_6分潮在渤海传播特征进行分析,发现:本海域存在7个M_6分潮无潮点,其中4个为逆时针旋转,3个为顺时针旋转。计算结果还发现:3个浅水分潮都是在近岸浅水海域振幅相对较大,这显然与浅水分潮的产生机制密切相关。 相似文献
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《热带海洋学报》2017,(3)
文章作为大亚湾潮汐动力学系列研究的第一部分,展现了大亚湾水动力的最新观测结果,并借助于不规则三角网格海洋模式建立了高时空分辨率的三维潮汐潮流数值模型,重现大亚湾潮位和潮流变化状况。结合实测资料与模拟结果,得到了较以往更为精细的大亚湾潮波系统特征。浅水分潮,尤其是六分之一日分潮在大亚湾内快速增长,成为大亚湾潮波系统的显著特征。在大亚湾范和港M_6分潮振幅达到与M_4、S_2分潮相同的量级。大亚湾外开阔海域的潮流以旋转流为主,但进入湾内后潮流椭圆迅速扁平化,往复流占据主导。在湾内主要潮流通道内,M_6潮流椭圆主轴流速超过了M_4和K_1分潮。潮能通量分析揭示了大亚湾内高频分潮的强耗散,M_6分潮的能量耗散率和半日周期内耗散的总能量均超过了M_4、M_2和K_1分潮。观测到的欧拉余流表现出其湾内不一致的大小潮变化以及湾外所受沿岸流的影响。模拟出的欧拉余流则揭示了大亚湾内的余流多涡旋结构和水体弱交换能力。 相似文献
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《中国海洋大学学报(自然科学版)》2017,(9)
大亚湾海域的潮位观测数据呈现出明显的"双峰"现象,在调和分析并选用分潮重构的过程中发现M_6分潮的异常增长是引起大亚湾内部出现该现象的主要原因,并且在湾口至湾顶两个测站之间M_6分潮增长了自身的近两倍。本文首先分析构建的FVCOM数值模型得到的M_6同潮图,发现M_6分潮在计算海域存在两个无潮点,一个位于湾外开边界附近,另一个位于东侧的陆地上,这与矩形等深渠道共振理论中在1/4,3/4处出现无潮点的理论是相符的,只是实际情况中由于浅水效应的影响,湾口处的无潮点被迫转移到陆地上。进一步进行了三组数值实验:改变水深和湾长后,大亚湾内的共振条件被破坏,M_6潮高均显著减小,证明共振效应确实是引起该分潮增大的原因;能量来源实验表明:M_6分潮的成长72%来源于自身成长,4.6%来源于M_2分潮非线性转化,23.4%来源于M_2和M_4分潮相互作用转化;若除去二次底摩擦,M_6分潮就不能通过各种非线性作用攫取能量,共振放大作用也就发挥不了任何作用。 相似文献
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《海洋技术学报》2023,(2)
全球潮汐预报模型在深水大洋具有较高的精度, 但在近岸强潮海区由于地形岸线、模型分辨率等原因精度不一, 难以直接应用。三门湾海域多年平均潮差4 m, 最大潮差可达7 m,是典型的强潮海湾, 为了评估TPXO9.0、TPXO9.0-atlas TOPEX/POSEIDON TIDES)、NAO.99b(National Astronomical Observatory of Japan)与GTM(Global Tide Model) 4 种预报模型在三门湾海域的预报精度, 本文分别通过上述4 个潮汐预报模型提取水动力数学模型开边界进行对比,并利用提取的开边界潮位对二维水动力模型进行驱动。通过计算分析潮位站实测数据与数值模拟结果的误差, 研究4 种预报模型模拟的三门湾潮汐变化得出, NAO.99b 模型在三门湾海域整体预报精度最佳, 分潮振幅、迟角和实测数据误差最小, TPXO9.0-atlas 分潮振幅模拟较好, 但迟角误差较大。对湾内四大分潮进行潮汐调和分析发现, 三门湾海域以半日潮为主, M2、S2 和K1分潮振幅由湾顶向湾口递减, O1分潮相反。 相似文献
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本文利用珠江口附近高栏站(GLN)、大万山站(DWS)和珠海站(ZUH)2018年4月-8月的实测潮汐资料对珠江口海域潮汐特征展开分析,并结合实测10m高度处风速资料分析该海域风特征。研究结果表明:(1)因观测期间为4-8月,受季风影响,三个站位均以南向或者偏南向为主,因有台风经临,风暴增水问题不容忽视。(2)观测期间,不同站位之间潮汐特征值并不相同,其中珠海站潮差最大,为109.7cm,大万山站潮差最小,为100.2cm;(3)不同月份之间,各站位月平均海平面并不一致,高栏站月均海平面最高,分别为248.32cm、260.09cm和262.55cm,大万山站月均海平面最低,分别为207.88cm、218.24cm和218.24cm。三个站位进行潮汐大多介于175-325cm之间。(4)观测期间大万山站、高栏站和珠海站的潮汐系数分别为1.74、1.78和1.49,施测海域的潮汐性质均属于不正规半日混合潮。该海域半日分潮以M_2分潮为主,等振幅分布大致呈现东北-西南走向。S_2分潮大致为M_2分潮的一半,迟角大于M_2分潮,证明其传播速度小于M_2分潮。全日分潮以K_1为主,等振幅线也大致呈现东北-西南走向。 相似文献
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乐清湾的潮位、潮流和余流特征 总被引:2,自引:1,他引:1
2008年7月至2009年4月在乐清湾进行了代表春、夏、秋、冬4个季节的航次调查,设置了Y4、Y14、Y15和A共4个连续观测站位,共得到12组实测的海流流速和10组CTD数据。采用潮汐调和分析法分析了距江厦潮汐能试验电站3 km处的潮汐站位连续19个月的潮位资料,结合调查数据特性和乐清湾潮汐特点,引入M2与S2、O1与K1、M4与MS4、2MS6与M6分潮之间的差比关系,对连续观测站位的潮位和潮流进行准调和分析。潮位的统计和准调和分析结果显示:Y4、Y14、Y15站位和潮汐站位8个分潮振幅和的航次调查平均值为3.75,4.02,3.94和4.03 m,(HO1+HK1)/HM2的航次调查平均值为0.32,0.28,0.32和0.24。Y4、Y14、Y15和潮汐站位的M4、MS4、M6和2MS6浅水分潮振幅的航次调查平均值分别为0.20,0.31,0.35和0.25 m,M6和2MS6浅水分潮振幅的航次调查平均值分别为0.03,0.15,0.17和0.15 m。不同航次调查4个连续观测站位涨潮最大流速的平均值为81.5 cm/s,落潮最大流速的平均值为103.1 cm/s。Y4、Y14和Y15站位潮流的M2和S2分潮振幅百分比分别为86%,65%和68%,浅水分潮振幅百分比分别为11%,29%和25%。M4、MS4分潮振幅之和分别是M6、2MS6分潮振幅之和的2.1,1.2和1.7倍。由潮位和潮流的分析结果可知:从乐清湾湾口至湾顶,潮汐逐渐增强,半日潮比率逐渐增大,半日潮型的特性更为明显;浅水分潮强度逐渐增加,其中M6和2MS6分潮强度增强更为明显。位于湾口的Y4站位在秋季(2008年10月)航次调查时的日平均余流流向为西南偏南方向,冬季(2009年1月)和春季(2009年4月)航次调查时的余流流向为东南偏南方向。Y4站位余流受灵霓大坝影响,大坝建成后湾口余流改变方向,向南流出乐清湾。位于湾顶的Y14站位,余流流速变化不大,但方向变化明显,夏季(2008年7月)为西南方向,秋季为西南偏南方向,冬季为西南偏西方向,春季又为西南偏南方向。Y15站位余流流速较小,但方向变化明显。A站位两个航次调查时的余流流向均为东北方向。 相似文献
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胶州湾水交换及湾口潮余流特征的数值研究 总被引:5,自引:3,他引:5
利用基于普林斯顿海洋模式建立的胶州湾及临近海域潮汐潮流数值模型,结合胶州湾口走航式声学多普勒海流剖面仪(ADCP)测流资料,研究了胶州湾口的潮(余)流特征,并在潮流模型的基础上耦合建立了水质模块,模拟了胶州湾的水交换过程。考虑M2,S2,K1,O1,M4和MS4六个主要分潮,胶州湾口潮流场的模拟与ADCP观测数据吻合较好。外湾口水道上的潮流非常强,大潮期间观测到201 cm/s的峰值流速。团岛岬角的两侧分别存在一个流向相反的余流涡旋,两涡旋在团岛附近辐合,形成了57 cm/s的离岸强余流。整个胶州湾平均水体存留时间为71 d,平均半交换时间为25 d。胶州湾水体交换能力在空间分布上有很大差异:湾口海域最强,向湾顶逐渐减弱。湾内存在两个弱交换区,分别位于湾的西-西南部和东北端,水体存留时间多超过80 d,湾西局部水域最长达120 d,而半交换时间也大多超过40 d。潮流场的结构、强度,以及与湾口距离的远近是造成湾内水交换能力空间差异的主要原因。 相似文献
12.
The tidal regime of Shark Bay, Western Australia 总被引:1,自引:0,他引:1
Murray C. Burling Charitha B. Pattiaratchi Gregory N. Ivey 《Estuarine, Coastal and Shelf Science》2003,57(5-6):725-735
A non-linear hydrodynamic model is used to describe the tidal dynamics of Shark Bay, Western Australia. The model is forced by tidal elevations generated by M2, S2, K1 and O1 constituent data at the open boundaries. The absence of suitable boundary data required a ‘calibration’ of the boundary condition against the known constituent data from within the model domain. The model provides a good match to the available field data, and allows the surface-level and current response to be resolved over the entire domain. Due to a near quarter-wave resonance of the semi-diurnal tide along the eastern Hopeless Reach, which increases the semi-diurnal tide by a factor of 2, the tidal characteristics on each of the Reaches are different: on the eastern Hopeless Reach the tides are mainly semi-diurnal while on the western Freycinet Reach the tides are mainly diurnal. The tidal range is also higher along Hopeless Reach. Tidal harmonics, generated by non-linearity, are important in the shallow regions. The tidal wave is shown to propagate as a progressive wave into the Bay. Substantial phase-lag, attenuation and dissipation occur over the Faure Sill, a major shallow region of the eastern reach of the Bay. Non-linear generation of the M4 and MS4 tides is also significant in this region. Depth-averaged residual currents are presented, which show a tidally generated circulation that is enhanced in regions of complex topography. Estimates of tidal dissipation indicate that although the total dissipation is small on a global scale, the areal average is comparable with the Gulf of Carpentaria and approximately one-quarter of the value estimated for the Patagonian Shelf. 相似文献
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基于普林斯顿海洋模式,通过干湿网格判别法引入潮汐潮流的漫滩过程,考虑M2,S2,K1,O1,M4和MS4六个主要分潮,建立了胶州湾潮汐潮流数值模拟和预报模型,研究了该海域潮汐潮流特征,并讨论了漫滩对潮流模拟的影响。与实测资料的对比验证表明,该模式能够对胶州湾的潮汐和潮流做出较为合理的预测。给出了胶州湾潮汐、潮流、余流等分布特征,模拟的潮流场以及余流场涡旋等现象与观测符合良好;计算了潮波能通量,从能量角度探讨了潮波的传播特性;对潮位与潮流场演变规律,以及潮能通量的分析表明,胶州湾内的潮波以驻波为主。通过数值试验发现,漫滩过程的引入对胶州湾潮流速度的模拟至关重要,不考虑漫滩过程的模式会夸大或者低估潮流流速。对于滩涂面积广阔的海域来说,潮流数值模式中考虑漫滩的影响是必要的。 相似文献
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The offshore tide becomes strongly distorted as it propagates into shallow estuarine systems. Observations of sea surface elevation and horizontal currents over periods ranging from three days to one year, at nine stations within Nauset inlet/estuary, document the non-linear interaction of the off-shore equilibrium tidal constituents. Despite strong frictional attenuation within the estuary, the overtides and compound tides of M2, S2 and N2, in particular, reach significant amplitude, resulting in strong tidal distortion. High frequency forced constituents in sea surface are phase-locked, consistently leading the forcing tides by 60–70°, resulting in a persistent distortion where falling tide is longer than rising tide. Forced constituents in currents are more nearly in phase with equilibrium constituents, producing flood currents which are shorter but more intense than ebb currents. A compound fortnightly tide, MSf, modulates the mean water level such that lowest tides occur during neap phase instead of spring phase. This fortnightly tide can be contaminated by storm surge, changing the phase characteristics of this constituent. Implications of the overtides, compound tides, and lower frequency tides on near-bed, suspended and dissolved material transport are profound. 相似文献
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南麂岛附近海域潮汐和潮流的特征 总被引:4,自引:2,他引:2
以2008年冬季在浙江近海南麂岛附近投放的4个底锚系观测的水位和流速资料为依据,分析了潮汐和潮流特征。水位谱分析结果显示半日分潮最显著,全日分潮其次;近岸的浅水分潮比离岸大。水位调和分析结果表明:潮汐类型均为正规半日潮,近岸处的平均潮差大于3m,最大可能潮差大于6m,潮汐呈现出显著的低潮日不等和回归潮特征。流速谱分析结果显示半日分潮流最强,全日分潮流其次,且比半日分潮流小得多;近岸浅水分潮流比远离岸显著。流速调和分析结果表明:潮流类型均为正规半日潮流,靠近岸的两个站浅水分潮流较显著;最显著的半日分潮流是M2分潮流,其最大流速介于0.32~0.48m/s之间,全日分潮流均很弱,最大流速小于0.06m/s。M2分潮流均为逆时针旋转,椭圆率越靠近海底越大;最大分潮流流速分布为中上层最大、表层略小、底层最小;最大分潮流流速方向的垂向变化很小,底层比表层略为偏左;最大分潮流流速到达时间随深度的加深而提前,底层比中上层约提前30min。潮流椭圆的垂向分布显示这里的半日分潮流以正压潮流为主;日分潮流则表现出很强的斜压性。 相似文献
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A three-dimensional (3-D) finite volume coastal ocean model (FVCOM) was used for the study of water cir culation and seawater exchange in the Benoa Bay, Bali Island. The M2 tidal component was forced in open boundary and discharge from six rivers was included in the numerical calculation. The M2 tidal elevation produced by the FVCOM has a good agreement with the observation data. The M2 tidal current is also suc cessfully calculated under the ebb tide and flood tide conditions. The non-linear M2 tidal residual current was produced by the coastline geometry, especially surrounding the narrow strait between the Serangan Is- land and the Benoa Peninsula. The tidal residual current also generated two small eddies within the bay and one small eddy in the bay mouth. The salinity distribution influenced by river discharge could be success- fully calculated, where the numerical calculation and the observation results have a good correlation (r2) of 0.75. Finally in order to examine the seawater exchange in the Benoa Bay, the Lagrangian particle tracking method and calculation of residence time are applied. The mechanism of particle transport to the flushing of seawater is depicted clearly by both methods. 相似文献
17.
基于FVCOM的泉州湾海域三维潮汐与潮流数值模拟 总被引:1,自引:0,他引:1
基于FVCOM海洋数值模式,采用非结构的三角形网格和有限体积法,建立了泉州湾海域高分辨率(26 m)的三维潮汐、潮流数值模型。模拟结果同2个验潮站和3个连续测流站的观测资料符合良好,较好地反映了泉州湾内潮汐、潮流运动的变化状况和分布特征,给出了M2、S2、K1、O1 4个主要分潮的同潮图、表层潮流椭圆分布,以及模拟区域内最大可能潮差、表层最大可能潮流流速和潮余流分布。分析表明,4个分潮的最大潮汐振幅和迟角差分别为219 cm和19°,85 cm和25°,26 cm和12°,26 cm和9°;石湖港以东海域的潮波为逆时针旋转的驻波,以西海域为前进波;最大可能潮差由湾口的8.0m向湾内增加至8.8 m。湾内潮流类型为规则半日潮流,落潮最大流速大于涨潮最大流速,北乌礁水道为强流区,表层最大可能潮流流速为2.4 m/s;湾口潮流运动以逆时针方向的旋转流形式为主,湾内的潮流运动以往复流形式为主,长轴走向主要沿着水道方向,与等深线和海岸线平行;四个分潮流表层最大流速分别为1.4 m/s,0.58 m/s,0.12 m/s,0.10 m/s。余流流速大小与潮流强弱有密切的联系,表、中、底层最大余流流速分别为26 cm/s,20 cm/s,16 cm/s,三者在水平方向基本呈北进南出的分布形态。 相似文献
18.
To clarify the time change in water exchanges between Ise Bay and the adjacent ocean, repeated hydrographic observations were
conducted along the longitudinal section in Ise Bay. The results show that the mixing condition at the bay mouth (Irago Strait)
changed fortnightly in summer. During the spring tides, the strait water below the pycnocline was well-mixed and nearly homogeneous.
By contrast, it was weakly stratified during the neap tide. There is a strong negative correlation between the tidal range
and the density difference between the upper and lower layers at the strait. In summer, the intrusion depth of oceanic water
into the bay and consequent hydrographic conditions inside the bay changed frequently according to the tidal strength. During
the spring tides a prominent bottom front was created at the bay mouth, indicating that the strait water, which is a mixture
of oceanic and bay waters, intruded through the middle layer. On the other hand, during the neaps, cold and saline oceanic
water intruded through the bottom layer into the bay. The intrusion depth is significantly correlated with the tidal range.
It is considered that the wellmixed strait water, which has a density equivalent to the middle layer inside the bay, is lighter
than the bottom bay water and thus intrudes through the middle layer during the spring tides, while insufficient mixing makes
the bottom water at the strait heavier than the bay water, leading to the bottom intrusion during the neap tides. 相似文献
19.
A vertically integrated 2D numerical model was developed for the simulation of major tidal constituents (M2, S2, N2, K1 and O1) in the Bay of Bengal. The bathymetry for the model domain was derived from an improved ETOPO5 dataset prepared in our earlier work. The simulated tidal elevations showed good agreement with the hourly tide gauge observations at Paradip, Visakhapatnam, and Chennai. The amplitudes and phases of M2, S2, K1, and O1 at the coastal stations, obtained from harmonic analysis of simulated tides, were found to agree well with those obtained from Admiralty Tide Tables with the RMS misfit 9.2, 5.6, 2.9 and 3.1 cm, respectively. In the Bay of Bengal, semi-diurnal tides (M2, S2, and N2) attain highest amplitudes (180, 80, 30 cm, respectively) in the Gulf of Martaban while amplitudes of diurnal tides (K1, O1) reaches maximum (20, 12 cm, respectively) in the Malacca Strait. The continental shelf in the head bay and along the southern coast of Myanmar is about 200 km wide and the amplitudes of semi-diurnal tides are doubled in these regions while the diurnal tides amplify only marginally, which is consistent with Clarke and Battisti theory. In the north eastern end of the head bay and the Gulf of Martaban, the geometrical configuration of the coastline, in addition to the wide continental shelf, could contribute to the amplification of both semi-diurnal and diurnal constituents. In the Malacca Strait, the amplitudes of both semi-diurnal and diurnal tides are found to increase gradually from the northern end to the 2.5°N and decreases towards southern boundary. The co-tidal and co-range charts of M2 and S2 tidal constituents also show the presence of two degenerate amphidromic points in the head bay. A virtual amphidromic point for M2 is identified in the Malacca Strait. 相似文献